JP3416612B2 - Construction method of reinforced concrete columns - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of constructing a reinforced concrete column used in a high-rise reinforced concrete building or the like.

[0002]

2. Description of the Related Art In recent years, construction materials such as concrete and rebar having a strength higher than that of conventional concrete have been developed, and high-rise reinforced concrete buildings have been constructed using these.

[0003]

The pillars of this high-rise reinforced concrete building have the following problems.

First, in a high-rise reinforced concrete building, since high-strength concrete having a larger unit cement amount than that of ordinary-strength concrete is used, the heat of hydration generated when hardening concrete is relatively large. In addition, in the columns of high-rise reinforced concrete buildings, the cross-sectional area is 1 m.
Since it is as large as around ^{2, the} heat of hydration associated with hardening of the concrete is less likely to diffuse out of the column member, and the temperature rise of the concrete after placing becomes very large. This increase in temperature reduces the compressive strength of concrete after hardening.

Further, when the cross-sectional area of the column becomes large, the volume of the cast concrete becomes large, so that cracks peculiar to the mass concrete are likely to occur at the time of hardening the concrete, and the lateral pressure applied to the formwork becomes large. turn into.

Further, the high strength concrete has a remarkable decrease in the yield strength after the maximum yield strength is exerted and the toughness of the column member is smaller than that of the ordinary strength concrete.

An object of the present invention is to reduce the temperature rise during hardening of concrete, which is a factor that hinders the development of compressive strength of concrete when constructing a column of a high-rise reinforced concrete building, and to provide greater toughness than that of a conventional reinforced concrete column. It is to provide a method of constructing a reinforced concrete column that can be provided to the column.

[0008]

In order to solve the above-mentioned problems, the method for constructing a reinforced concrete column according to claim 1,
For example, as shown in FIGS. 1 (a) to 1 (d) (FIGS. 3 (a) to (d)), among a large number of small holes and a large number of concavities and convexities, approximately at the center of the pillar 1 (2) to be constructed. A step of arranging a thin-walled cylinder 11 (21) having at least one in the vertical direction and arranging a reinforcing bar 12 (22) inside the pillar 1 (2) to be constructed so as to surround the cylinder 11 (21). And the cylinder 11
The step of placing concrete 13 (23) inside (21), and the form 15 (2) around the rebar 12 (22).
5) The step of building in and the step of placing concrete 14 (24) between the cylinder 11 (21) and the mold 15 (25) are provided.

According to the first aspect of the present invention, the step of pouring concrete includes the step of pouring concrete inside the tube, and the step of pouring concrete between the tube and the mold. Since it is divided into two steps, it is possible to diffuse the heat of hydration generated during hardening of the concrete and suppress the temperature rise of the concrete after pouring, especially the concrete at the center of the column cross section. Therefore, when the concrete is hardened, the increase in the compressive strength of the concrete is not hindered by the temperature rise, and the compressive strength of the concrete can be made uniform between the central section and the outer peripheral section of the column. Further, the concrete cast inside the cylinder and the concrete cast between the cylinder and the mold are thin-walled ones having at least one of a large number of small holes and a large number of irregularities. By being placed on both sides of the cylinder, the integrity of the two becomes high. From the above matters, it is possible to suppress the occurrence of cracks peculiar to mass concrete, and the construction method of the present reinforced concrete column can be applied to a column having a large cross-sectional area in a high-rise reinforced concrete building.

Further, the concrete cast inside the cylinder is cured by the concrete cast between the cylinder and the mold so as to surround the concrete. It is possible to promote the increase of the compressive strength when the cast concrete is cured. Further, in the step of placing concrete, the concrete is placed inside a thin-walled cylinder having at least one of a large number of small holes and a large number of irregularities arranged vertically in the approximate center of the pillar to be constructed. Since it is divided into two steps, that is, the step of placing concrete between the cylinder and the mold, as compared with the case of placing concrete on the entire pillar at once,
Separation of coarse aggregate in ready-mixed concrete can be reduced. Further, the lateral pressure applied to the formwork is given only by the concrete that is placed between the cylinder and the formwork. Such lateral pressure can be reduced.

The invention according to claim 2 is, for example, as shown in FIG.
-(D) (Figs. 3 (a)-(d)), in the method for constructing a reinforced concrete column according to claim 1, the concrete 13 (2) cast inside the cylinder 11 (21) is used.
After the temperature rise due to the heat of hydration in 3) has subsided, the cylinder 11
Concrete 14 (24) is placed between (21) and the form 15 (25).

According to the second aspect of the present invention, the same effect as that of the first aspect can be obtained, and after the temperature rise due to the heat of hydration of the concrete placed inside the cylinder is suppressed, Since concrete is placed between the formwork and the heat of hydration generated during hardening of the concrete, it is possible to reliably suppress the temperature rise of the concrete after placing, especially the concrete at the center of the column cross section. It will be possible.

The invention according to claim 3 is, for example, as shown in FIG.
~ (D) (Fig. 3 (a) ~ (d)), in the method for constructing a reinforced concrete column according to claim 1 or 2, the reinforcing bar 12 (22) is outside the tube 11 (21). Is provided with a plurality of main reinforcements 12a (22a), and a plurality of main reinforcements 12a (22a) wound around the outside of the cylinder 11 (21) so as to surround the reinforcement 12b (22b). . Here, it is preferable to use a spiral reinforcement made of high-strength steel as the strip reinforcement.

According to the third aspect of the present invention, the same effect as that of the first or second aspect is obtained, and the concrete that is cast inside the cylinder is wound around the outside so that the concrete is wound. Since it is restrained by, the strength and toughness of the concrete cast inside the cylinder are enhanced. Therefore, the construction method of the present reinforced concrete column can be applied to a column in a high-rise reinforced concrete building subjected to high compressive force and high shear force. Further, since the strength and toughness of the concrete cast inside the cylinder are increased, the cross-sectional area of the column can be reduced and the column can be made slim. As a result, the heat of hydration of concrete cast on the pillars is more easily diffused, and the increase in compressive strength during hardening of the concrete is further promoted.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a method for constructing a reinforced concrete column according to the present invention will be described in detail below with reference to the drawings. The construction method of the reinforced concrete column of each embodiment is
It is applied when constructing columns of high-rise reinforced concrete buildings.

[First Embodiment] FIGS. 1A to 1D.
[Fig. 2] is a schematic view showing a procedure of a method for constructing a reinforced concrete column of the present embodiment, and Fig. 2 is a partial perspective view showing a reinforced concrete column constructed by the same example.

The procedure of the method for constructing a reinforced concrete column according to this embodiment will be described. First, as shown in FIG. 1 (a), a cylinder 1 made of a metal lath is approximately at the center of a pillar 1 to be constructed.
1 is arranged in the vertical direction, and a reinforcing bar 12 is arranged inside the pillar 1 to be constructed so as to surround the cylinder 11.

Here, the reinforcing bar 12 includes a plurality of main bars 12a arranged outside the cylinder 11 and the main bars 12a.
Wrapped around the outside of the cylinder 11,
It is composed of a stirrup 12b made of a high-strength spiral muscle. In addition, the voids (small holes) of the metal lath forming the cylinder 11 are provided inside the concrete 13 described later.
When pouring, the mortar component of the concrete 13 does not leak out, and the breathing water is formed to a size that allows passage.

Subsequently, as shown in FIG. 1 (b), concrete 13 is placed inside the cylinder 11.

In this state, the heat of hydration of the concrete 13 cast inside the cylinder 11 is diffused to the outside by leaving it for a predetermined time according to the ambient temperature. After the temperature rise of the concrete 13 has subsided, as shown in FIG. 1 (c), after the formwork 15 was built around the rebar 12,
Concrete 14 is placed between the cylinder 11 and the mold 15.

When the concrete 14 is hardened, as shown in FIG. 1 (d), the mold 15 is removed from the mold to complete the construction of the reinforced concrete column by the method for constructing the reinforced concrete column.

[Second Embodiment] FIGS. 2A to 2D.
[Fig. 3] is a schematic diagram showing a procedure of a method for constructing a reinforced concrete column according to the present embodiment.

In the method for constructing a reinforced concrete column according to the present embodiment, instead of the cylinder 11 made of metal lath and the strip 12b made of high-strength spiral reinforcement in the method for constructing a reinforced concrete column according to the first embodiment, respectively,
Although the cylinder 21 made of a corrugated iron plate having a large number of irregularities and the substantially ring-shaped stirrup 22b are used, the other points are:
This is the same as the method for constructing a reinforced concrete column according to the first embodiment.

As described above, according to the method for constructing a reinforced concrete column described in each of the above-mentioned embodiments, the concrete 13, 1
4 (23, 24) is placed in the cylinder 11 (2
1) the step of placing concrete 13 (23) inside and the step of placing concrete 14 (24) between the cylinder 11 (21) and the form 15 (25). Because it is divided, concrete 13, 14 (23,
24) The heat of hydration generated at the time of hardening can be diffused to suppress the temperature rise of the concrete 13, 14 (23, 24) after casting, especially the concrete 13 (23) at the center of the column cross section. Therefore, the concrete 13,14
At the time of hardening (23, 24), the increase in the temperature does not hinder the increase of the compressive strength of the concrete 13, 14 (23, 24), and the concrete 13, 14 (23, The compressive strength of 24) can be made uniform. In addition, concrete 13 (23) cast inside the cylinder 11 (21) and concrete 14 (24) cast between the cylinder 11 (21) and the mold 15 (25). By being cast on both sides of the cylinder 11 made of a metal lath (the cylinder 21 made of a corrugated iron plate), the two are highly integrated. From the above matters, it is possible to suppress the occurrence of cracks peculiar to mass concrete, and the construction method of the present reinforced concrete column can be applied to a column having a large cross-sectional area in a high-rise reinforced concrete building.

The concrete 13 (23) placed inside the tube 11 (21) is placed between the tube 11 (21) and the mold 15 (25) so as to surround it. Since the concrete 14 (24) is cured, the compressive strength of the concrete 14 (24) cast inside the cylinder 11 (21) at the time of hardening can be promoted. In addition, concrete 13,14
Pillar 1 to be constructed in the process of placing (23, 24)
(2) a step of placing concrete 13 (23) inside a cylinder 11 (cylinder 21 made of corrugated iron plate) made of metal laths arranged in the vertical direction substantially at the center, and the cylinder 11 (2
Concrete 14 is provided between 1) and the mold 15 (25).
Since it is divided into two steps, that is, the step of placing (24), it is possible to reduce the separation of the coarse aggregate in the ready-mixed concrete as compared with the case where the concrete is placed all over the pillar at once. it can. Moreover, since the lateral pressure applied to the mold 15 (25) is given only by the concrete 14 (24) that is cast between the cylinder 11 (21) and the mold 15 (25), The side pressure applied to the formwork 15 (25) can be reduced as compared with the case where concrete is poured at once.

Further, after the temperature rise due to the heat of hydration of the concrete 13 (23) cast inside the cylinder 11 (21) has subsided, the cylinder 11 (21) and the mold 15 (2).
Since the concrete 14 (24) is placed between the concrete 5 and 5), the heat of hydration generated at the time of hardening the concrete 13, 14 (23, 24) is diffused, and the concrete 1 after the placing
3, 14 (23, 24), in particular, the temperature rise of the concrete 13 (23) at the center of the cross section of the column can be surely suppressed.

The concrete 13 (23) cast on the inside of the cylinder 11 (21) is restrained by the stirrup 12b (22b) made of high-strength spiral reinforcement wound around the outside thereof. Therefore, the concrete 13 (2) cast inside the cylinder 11 (21)
The strength and toughness of 3) are improved. In particular, since the concrete 13 is constrained by the stirrup 12b made of high-strength spiral reinforcement, the strength and toughness of the concrete 13 are significantly increased. Therefore, the construction method of the present reinforced concrete column can be applied to a column in a high-rise reinforced concrete building subjected to high compressive force and high shear force. Further, since the strength and toughness of the concrete 13 (23) cast inside the cylinder 11 (21) are increased, the cross-sectional area of the pillar 1 (2) is reduced, and the pillar is made slim. be able to. As a result, the heat of hydration of the concrete placed in the pillar 1 (2) is more easily diffused, and the concrete 13, 14 (23, 2
The increase of the compressive strength at the time of curing of 4) is further promoted.

The method for constructing a reinforced concrete column according to the present invention is not limited to the above-mentioned embodiments, and various improvements and design changes may be made without departing from the spirit of the present invention. For example, in the first embodiment, various metal laths such as flat laths, cobras, and corrugated laths can be used as the metal laths that form the cylinder 11. Further, the cylinder in the present invention is not limited to the above metal lath, and is made of a thin material other than the metal lath having a large number of small holes, such as punching metal or a carbon fiber net having a large number of small holes. You can
Further, in the second embodiment, instead of the tube 21 made of a corrugated iron plate, a tube made of a steel pipe or the like having a large number of irregularities such as ribs on the surface may be used. Further, in the first embodiment, the stirrup 12 made of high-strength spiral muscles
An example in which a substantially ring-shaped stirrup is used instead of b, and an example in which a thin-walled cylinder having a large number of small holes such as a metal lath is used in place of the cylinder 21 made of a corrugated iron plate in the second embodiment Included in the method for constructing a reinforced concrete column according to the present invention. Further, the cylinder 11 of the first embodiment and the cylinder 21 of the second embodiment each have at least one of a large number of small holes and a large number of irregularities, but instead of this, An example of a reinforced concrete column of the present invention is also one that uses a thin-walled cylinder having both a large number of small holes and a large number of irregularities, such as corrugated metal lath, punching metal, and carbon fiber net. In addition, it goes without saying that the specific detailed structure and the like can be appropriately changed.

[0029]

According to the invention described in claim 1, the step of placing concrete comprises placing concrete inside the tube, and placing concrete between the tube and the mold. Since it is divided into two steps, it is possible to diffuse the heat of hydration generated during hardening of the concrete and suppress the temperature rise of the concrete after pouring, especially the concrete at the center of the column cross section. Therefore, when the concrete is hardened, the increase in the compressive strength of the concrete is not hindered by the temperature rise, and the compressive strength of the concrete can be made uniform between the central section and the outer peripheral section of the column. Further, the concrete cast inside the cylinder and the concrete cast between the cylinder and the mold are thin-walled ones having at least one of a large number of small holes and a large number of irregularities. By being placed on both sides of the cylinder, the integrity of the two becomes high. From the above matters, it is possible to suppress the occurrence of cracks peculiar to mass concrete, and the construction method of the present reinforced concrete column can be applied to a column having a large cross-sectional area in a high-rise reinforced concrete building.

Further, the concrete cast inside the cylinder is cured by the concrete cast between the cylinder and the mold so as to surround the concrete. It is possible to promote the increase of the compressive strength when the cast concrete is cured. Further, in the step of placing concrete, the concrete is placed inside a thin-walled cylinder having at least one of a large number of small holes and a large number of irregularities arranged vertically in the approximate center of the pillar to be constructed. Since it is divided into two steps, that is, the step of placing concrete between the cylinder and the mold, as compared with the case of placing concrete on the entire pillar at once,
Separation of coarse aggregate in ready-mixed concrete can be reduced. Further, the lateral pressure applied to the formwork is given only by the concrete that is placed between the cylinder and the formwork. Such lateral pressure can be reduced.

According to the second aspect of the present invention, the same effect as in the first aspect can be obtained, and after the temperature rise due to the heat of hydration of the concrete cast inside the cylinder is subsided,
Since concrete is placed between the cylinder and the form, the heat of hydration generated during hardening of the concrete is diffused, and the temperature rise of the concrete after placing, especially the concrete at the center of the column cross section, is ensured. It becomes possible to suppress.

According to the invention of claim 3, the same effect as that of claim 1 or 2 can be obtained, and the concrete cast inside the cylinder is wound by the strips wound so as to surround the outside thereof. Since it is restrained, the strength and toughness of the concrete cast inside the cylinder are enhanced. Therefore, the construction method of the present reinforced concrete column can be applied to a column in a high-rise reinforced concrete building subjected to high compressive force and high shear force.
Further, since the strength and toughness of the concrete cast inside the cylinder are increased, the cross-sectional area of the column can be reduced and the column can be made slim. As a result, the heat of hydration of concrete cast on the pillars is more easily diffused, and the increase in compressive strength during hardening of the concrete is further promoted.

[Brief description of drawings]

FIG. 1 shows an example of a method for constructing a reinforced concrete column of the present invention, and is a schematic view showing the procedure of the example in the order of (a) to (d).

FIG. 2 is a partial perspective view showing a reinforced concrete column constructed by the same example.

FIG. 3 shows another example of the method for constructing a reinforced concrete column of the present invention, and is a schematic view showing the procedure of the example in the order of (a) to (d).

[Explanation of symbols]

1, 2 pillars 11,21 cylinder 12,22 Rebar 12a, 22a main line 12b, 22b stirrup 13,14,23,24 Concrete

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-60-168822 (JP, A) JP-A-62-197539 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) E04G 21/02 103 E04B 1/16 E04C 3/34

Claims (3)

(57) [Claims] 1. A thin-walled cylinder having at least one of a large number of small holes and a large number of irregularities is arranged in the vertical direction substantially at the center of a pillar to be constructed, and the cylinder is provided inside the pillar to be constructed. Arranging the reinforcing bars so as to surround it, placing concrete inside the cylinder, building a form around the reinforcing bar, placing concrete between the cylinder and the form A method for constructing a reinforced concrete column, comprising the steps of: 2. The method for constructing a reinforced concrete column according to claim 1, wherein after the temperature rise due to the heat of hydration of the concrete placed inside the cylinder has subsided, concrete is placed between the cylinder and the formwork. A method for constructing a reinforced concrete column, which is characterized by placing. 3. The method for constructing a reinforced concrete column according to claim 1, wherein the reinforcing bar is a plurality of main reinforcing bars arranged outside the cylinder,
A method for constructing a reinforced concrete column, characterized in that the main bars are provided with a band bar wound so as to surround the outside of the cylinder.